Development of an experimental profile database for the scrape-off layer

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Porter, 1 W.M. Meyer, 1 A.W. Leonard, 2 T.H.

Wischmeier 3 N.H. Brooks, 2 J. Harhausen, 3 H.W. Müller, 3 J.

teams 1 Lawrence Livermore National Laboratory,

CA, USA 3 Institute for Plasma Physics, Garching,

Albuquerque, NM, USA Presented at the 9 th ITPA

1 Development of an experimental profile database for the scrape-off layer M. Groth, 1 G.D. Porter, 1 W.M. Meyer, 1 A.W. Leonard, 2 T.H. Osborne, 2 D.P. Coster, 3 A. Kallenbach, 3 M. Wischmeier 3 N.H. Brooks, 2 J. Harhausen, 3 H.W. Müller, 3 J.G. Watkins 4 And the ASDEX Upgrade and DIII-D teams 1 Lawrence Livermore National Laboratory, Livermore, CA, USA 2 General Atomics, San Diego, CA, USA 3 Institute for Plasma Physics, Garching, Germany 4 Sandia National Laboratory, Albuquerque, NM, USA Presented at the 9 th ITPA Divertor and SOL working group meeting Garching, Germany May 7-10, 2007

2 The.DIV branch of the ITPA Pedestal Profile Database pursues the same goals as its parent Create repository for blessed SOL data Facilitate cross-machine comparison of SOL profiles Provide data for SOL modeling and its validation Promote collaboration between existing devices, e.g., pedestal fueling experiments Format: MDSplus-based data structure MDSplus trees MDSplus commands, e.g., data=mdsvalue( MDSplus tag ) Database tree locations: AUGDIV (and AUGPED) at IPP Garching PED_D3D at General Atomics 2

3 Current status of data in the.div branch Available shots AUGDIV: e.g., divertor characterization: Ohmic density scan, H-mode PED_D3D: H-mode (JET/DIII-D similarity experiment) L-mode density scan (AUG/DIII-D fueling study) Available data (= data + geometry) Upstream profiles for n e, T e, T i, f Z (data and mtanh fits) Radiation profiles from bolometry Divertor profiles of j sat, n e, T e, P target, brightness at various emission lines Sets of independent coordinates: Ψ N, R-R sep,omp, and ds sep,target 3

4 PED_D3D tree structure contains both pedestal and SOL data Top-level branches for equilibrium, pedestal, and divertor data 4

5 PED_D3D tree structure contains both pedestal and SOL data Top-level branches for equilibrium, pedestal, and divertor data.div branch with 0-D, 1-D, and 2- D branches; time-averaged and time-resolved (for ELMs) 5

6 PED_D3D tree structure contains both pedestal and SOL data Top-level branches for equilibrium, pedestal, and divertor data.div branch with 0-D, 1-D, and 2- D branches; time-averaged and time-resolved (for ELMs).TWOD branch contains profile data, e.g., particle and heat fluxes, target n e and T e 6

7 PED_D3D tree structure contains both pedestal and SOL data Top-level branches for equilibrium, pedestal, and divertor data.div branch with 0-D, 1-D, and 2- D branches; time-averaged and time-resolved (for ELMs).TWOD branch contains profile data, e.g., particle and heat fluxes, target n e and T e JSATDIV: data and independent variables, run-specifics 7

8 PED_D3D tree structure contains both pedestal and SOL data Top-level branches for equilibrium, pedestal, and divertor data.div branch with 0-D, 1-D, and 2- D branches; time-averaged and time-resolved (for ELMs).TWOD branch contains profile data, e.g., particle and heat fluxes, target n e and T e JSATDIV: data and independent variables, run-specifics SPECTRO branch: line-emission profiles, e.g., H α, H β, CIII 8

9 PED_D3D tree structure contains both pedestal and SOL data Top-level branches for equilibrium, pedestal, and divertor data.div branch with 0-D, 1-D, and 2- D branches; time-averaged and time-resolved (for ELMs).TWOD branch contains profile data, e.g., particle and heat fluxes, target n e and T e JSATDIV: data and independent variables, run-specifics SPECTRO branch: line-emission profiles, e.g., H α, H β, CIII HALPHA: data, wavelength, and geometry information 9

10 Example: Dimensionally and operationally similar Ohmic plasmas in ASDEX Upgrade and DIII-D shot I P [MA] / B T [T] P in [MW] P rad [MW] (f rad ) <n e > [10 19 m -3 ] divertor configuration first-wall ASDEX-U / -1.9 (fwd) q δ low (57%) 2.6 Vertical (cryo) Div - C, MC - W DIII-D / -2.0 (fwd) (44%) 2.6 Inner plate 45, outer horizontal (no cryo) Div & MC - C 10

11 Lower single null plasmas with vertical (AUG) and semihorizontal (DIII-D) target plate configurations Filtered line monitors (D α, CIII) Thomson Scattering (n e, T e ) Langmuir Probes (j sat ) 11

12 Carbon copy upstream profiles in AUG and DIII-D Upstream data mapped to flux coordinates at the outer midplane: PSIN DIII-D AUG 12

13 Similar particle flux profiles to outer plate, but inner plate profile suggests partially detached plasma for DIII-D Perpendicular component of j sat, obtained from strike point sweeps mapped to dssep DIII-D j sat profile for inner plate peaks ~6 cm in common flux region, for AUG at the inner separatrix Different LP probe designs: flat (AUG) versus domed (DIII-D) probe heads DIII-D x sin(θ) AUG PFR Com SOL 13

14 In/out asymmetric divertor D α traces are consistent with Langmuir probe measurements Nearly-normal (AUG) versus vertical (DIII-D) viewing geometries likely to affect shape and magnitude of the profiles DIII-D AUG x 10 DIII-D AUG 14

15 Carbon emission profile (and tangential camera data) indicative of inner divertor plasma < 2 ev for DIII-D Similar CIII emission profiles at outer plate Inner divertor CIII emission peaks in common SOL (AUG) and private flux region (DIII-D) DIII-D AUG 15

16 Experimental database facilitates comparison with SOLPS / UEDGE modeling database Modeling database originally developed by David Coster, IPP Garching, for SOLPS, recently adapted for UEDGE Tree structure mainly for code output Enables platform-independent code-code comparison Tree structure includes synthetic diagnostics for simulation validation against experiments Set of common independent parameters required, e.g., R-R sep at the outer midplane 16

17 Summary and outlook: database most useful when physics topic-driven Extension of pedestal profile database to (currently divertor) SOL Two different local versions: AUGDIV and.div in PED_D3D MDSplus-based data structure In process of finalizing tree structure for a central ITPA database Data available upon request Need to decide how we want to share the database, to transfer data, to grant access, etc. Database is a powerful tool to compare SOL profiles from different devices, and with simulations from edge codes AUG / DIII-D core plasma fueling experiment: effect of divertor geometry on divertor performance and core plasma fueling Extension of database to other devices 17

Experimental results and modelling of ASDEX Upgrade partial detachment

Experimental results and modelling of ASDEX Upgrade partial detachment M. Wischmeier 1 With thanks to X. Bonnin 2, P. Börner 3, A. Chankin 1, D. P. Coster 1, M. Groth 4, A. Kallenbach 1, V. Kotov 3, H.